Self-contained accordian shutter system

ABSTRACT

A method for manufacturing protective shutters is provided. The method may include: shaping metal to form shutter components, the shutter components comprising at least a top guide piece and a bottom guide piece, a plurality of shutter blades, and side supports; cutting the shutter components to predetermined dimensions; drilling screw holes into the shutter components at predetermined locations; providing a plurality of guide wheels for guiding the shutter blades along a hollow portion in the top guide piece; providing a plurality of protruding pieces for protruding from joints where two shutter blades attach and for guiding the shutter blades along the top and bottom guide pieces; and providing mounting hardware for attaching the protective shutters to a fixed structure and for attaching the shutter components together. The shutter components, guide wheels, protruding pieces, and mounting hardware are for being packaged together for delivery to a recipient.

CROSS REFERENCE TO RELATED APPLICATIONS

The instant application claims priority to 61/006,964 filed Feb. 8, 2008, the disclosure of which is incorporated by reference herein in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to accordion hurricane shutters. More specifically, the present invention relates to a self-contained shutter assembly system utilizing pre-assembled components.

2. Description of Prior Art

Shutters are used for decoration, security, and weather protection. Recent powerful hurricanes in the southeastern United States have raised building protection as a serious issue. Shutters are often used in these and other regions to provide protection during hurricanes and other strong storms. Shutters provide light and air during a storm, while protecting the building and the occupants from airborne objects. Many southeastern portions of the United States require that homes and businesses have metal storm shutters over windows to protect the interior of the buildings during extreme weather, which is common to this part of the country.

A popular hurricane shutter is the “accordion” shutter in which several shutter blades rotatably interconnect. Conventionally, accordion folded hurricane shutters are made from extruded aluminum with blade assemblies of set dimensions and angular orientation. A blade assembly usually includes two blades joined with an intermediate longitudinal knuckle joint, and knuckle elements on each longitudinal free edge. U.S. Pat. Nos. 5,458,179 and 5,097,883 show examples of such systems. Due to the rotation, the blade assemblies can be placed in (1) a retracted position in which the blades are substantially horizontal and recessed from the opening (e.g., window, door) they are designed to protect, and (2) a deployed position in which the blade assemblies extend from the opposing edges of the opening until the set angular orientation between blades is reached by rotational limit of the knuckle joints.

The bulk of the components for an accordion shutter system are made from extruded aluminum. In this process, an appropriate die is designed based on the desired cross section of the component. Heated aluminum is extruded through the die and cooled into its final form. The extruded aluminum panels are generally about 16 feet long, which is longer than would ever be used as a single component of the accordion shutter. These bulk panels are sold to installers, distributors, and retailers for installation in local homes and businesses.

The above methodology has several drawbacks, particularly for a homeowner or business who would like to install an accordion shutter system. One drawback is that, because each piece of aluminum is typically longer than the opening over which it will be used, each piece needs to be individually cut to the appropriate size of the opening. Similarly, certain mounting components (e.g. headers) need to be customer-drilled to make holes for mounting screws. As a result, the uniformity and quality of the resulting installation—from both aesthetic and safety viewpoints—depends considerably on the skill level of the installer. Since the majority of the public does not have the necessary tools to properly cut aluminum, an independent installer is usually required, with associated expenses and difficulties.

Another drawback of the conventional system is that excess aluminum is wasted. The cutting process typically produces scrap pieces of aluminum which are too small for practical use. Since the recycle value of the metal is high, manufacturers typically keep this scrap aluminum, and store it in a secure location to prevent theft pending recycling. However, the volume of scrap from a home installation is small, so that a home purchaser does not have the same incentive to recycle the metal. Thus, the homeowner will typically throw it away. Even if a third-party installer is used, they must still collect the material and transport it to recycle locations.

Another drawback is the presence of counterfeit and/or substandard components on the market. Third party installers may be using some or all of these components along with legitimate or high-quality components. If the system fails due to the counterfeit and/or substandard components, the homeowners may unfairly sue the legitimate manufacturer.

SUMMARY OF THE INVENTION

According to an embodiment of the invention, a method for manufacturing protective shutters is provided. The method may include: shaping metal to form shutter components, the shutter components comprising at least a top guide piece and a bottom guide piece, a plurality of shutter blades, and side supports; cutting the shutter components to predetermined dimensions; drilling screw holes into the shutter components at predetermined locations; providing a plurality of guide wheels for guiding the shutter blades along a hollow portion in the top guide piece; providing a plurality of protruding pieces for protruding from joints where two shutter blades attach and for guiding the shutter blades along the top and bottom guide pieces; and providing mounting hardware for attaching the protective shutters to a fixed structure and for attaching the shutter components together, wherein all of the shutter components, guide wheels, protruding pieces, and mounting hardware are for being packaged together for delivery to a recipient.

The above embodiment may have various optional features. For example, the method may include pre-inserting the guide wheels into joints where the shutter blades meet, before delivery to a recipient. The method may include pre-inserting the protruding pieces into joints where the shutter blades meet, before delivery to a recipient. The method may include pre-attaching the shutter blades to one another to form at least one shutter door, before delivery to a recipient. The method may include pre-attaching a side support to an end of the shutter door, before delivery to a recipient. The shutter components may include at least one locking blade. The method may include attaching the one locking blade to an end of the shutter door opposite the side support end. The shutter components may include a shutter hold-back device. The protruding pieces may be made of nylon or plastic. The shutter components may be made of aluminum. The shutter components may be formed in an aluminum-extrusion process. The shutter hold-back device may be made of either nylon or plastic.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is further described in the detailed description which follows, in reference to the noted plurality of drawings by way of non-limiting examples of certain embodiments of the present invention, in which like numerals represent like elements throughout the several views of the drawings, and wherein:

FIG. 1 is a schematic of a shutter curtain assembly.

FIGS. 2 and 3 are schematics of a side cutaway view of a shutter curtain assembly.

FIG. 4 is a schematic of a cross section view of an individual blade portion.

FIG. 5 is a schematic of a close-up view of the shutter curtain assembly shown in FIG. 2.

FIG. 6 is a schematic of a self-contained kit containing shutter curtain assembly components.

FIGS. 7 a and 7 b are schematics of a top view of a top guide.

FIG. 8 is a schematic of a top guide fixed to a metal brace by a bolt.

FIG. 9 is a schematic of a pre-assembled left-door.

FIGS. 10 a and 10 b are schematics of a shutter hold-back device.

FIG. 11 is a schematic of a bottom guide assembly.

DESCRIPTION OF PREFERRED EMBODIMENTS

Referring now to FIG. 1, embodiments of the invention are directed to a self contained collection of components to create an accordion shutter for an opening. The components are preferably all pre-cut to predetermined lengths, such that the individual installer will not have to cut any parts. The various components that need to be secured to a structure via screws or bolts are also preferably pre-drilled at uniform distances to avoid any need for the installer to drill holes. The various components are pre-assembled into workable modules for each installation.

FIG. 1 shows a shutter curtain assembly 10 according to an embodiment of the present invention.

The shutter curtain assembly 10 is used to cover, for example, a garage, doorway, window or any similar opening which is defined by a rectangular or square frame 12 forming an interior aperture. The shutter curtain assembly is made up of a plurality of individual blade portions 14 that are interlockingly connected. The connected blade portions 14 form a substantially accordion shape when they are drawn across the framed opening into a deployed position. The blade portions 14 each have a substantially equal length, and when connected together extend across the width of the opening. The blade portions 14 are preferably constructed of a high-strength tempered aluminum alloy, however they can also be constructed of any other desirable metal, polymer, or combination thereof exhibiting the necessary characteristics of strength and durability. Individual blades may also be made of transparent material, or have holes therein to allow for light and air passage.

Referring to FIG. 4, an individual blade portion 14 is shown in cross section. The blade portion 14 includes a flat central portion 16 to which is attached a first interlocking portion 18 and a second interlocking portion 20. The first interlocking portion 18, the second interlocking portion 20 and the flat central portion 16 extend the entire length of the shutter blade from the top of the framed opening 12 to the bottom as shown in FIG. 1.

The first interlocking portion 18 is defined by a substantially partial-cylindrical-shaped portion which extends from the flat central portion the length of the blade. The first portion 18 encompasses an angle that is slightly greater than 180 degrees of a cylinder. The partial cylinder forms a hollow interior between opposing edges with a given inner diameter. A first inwardly-directed tang 22 projects from one of the edges of the semi-cylinder and a second inwardly-directed tang 24 projects from the other edge of the semi-cylinder. The inwardly-directed tangs 22 and 24 extend the entire length of the blade and create opposite and abutting surfaces within the partial cylindrical opening of the first interlocking portion. The tang 22 is a pointed, inwardly-directed portion while the tang 24 forms a more pronounced and inwardly-directed dog leg.

The second interlocking portion 20 is defined by a partial cylindrical shaped portion, preferably substantially semi cylindrical-shaped, which extends from the flat central portion opposite the first interlocking portion and the length of the blade. The second interlocking portion 20 has a smaller diameter to allow for insertion into the first interlocking portion. Similarly to the first interlocking portion, the second interlocking portion forms an angle that is slightly greater than a semi-cylinder and has a hollow interior between opposing edges.

A first tang 26 projects outwardly from one of the edges of the semi-cylinder 20 and a second tang 28 projects outwardly along the other edge of the semi-cylinder. The outwardly-directed tang 26 is pointed similar to the inwardly-directed tang 22, while the outwardly-directed tang 28 forms a dog leg similar to the inwardly-directed tang 24.

The second interlocking portion 20 includes a leg 30 which is angled relative to the flat central portion 16 of the blade and which offsets the second interlocking portion 20 from the axis of the central portion 16. A reinforcing portion or flange 32 can be provided that extends from the connection between the leg 30 and the flat central portion 16 on a side opposite the leg. Such a flange 32 may strengthen the connection between the second interlocking portion and the blade, either by touching in the deployed position or under severe impact (causing additional flex in the shutter which is not present under normal conditions). This contact is best seen in FIG. 4, in which the flange 32 is in abutting contact with the tang 22″ of the first interlocking portion 18 when the shutter blades 14 are pivoted to the expanded position shown in FIG. 2.

Referring again to FIG. 4, the connection between the blade portion 14 and succeeding blade portions 14′ and 14″ is shown. A plurality of blade portions are interlockingly connected to form a substantially accordion-shaped shutter assembly. A first subsequent blade portion 14′ is shown in phantom and includes a second interlocking portion 20′ having outwardly-directed tangs 26′ and 28′. The second interlocking portion 20′ is slidingly inserted within corresponding first interlocking portion 18 of blade portion 14 the length of the blade portion 14. The smaller diameter semi-cylinder and the outwardly-directed tangs of the second interlocking portion 20′ are coaxially encapsulated within the hollow interior of the first interlocking portion 18. A predetermined range of pivotal movement is permitted between the blade 14′ and the blade 14 until one of the inwardly-directed tangs 22 and 24 of the first interlocking portion 18 engage the outwardly-directed tangs 26′ and 28′ of the second interlocking portion 20, at which point the blade 14′ is at a maximum pivotal position relative to the blade 14.

Similarly, the opposite second interlocking portion 20 of blade 14 is slidably inserted within a corresponding first interlocking portion 18″ of blade 14″, indicated in phantom. The inwardly-directed tangs 22″ and 24″ of the interlocking portion 18″ encircle the outwardly-directed tangs 26 and 28 of the interlocking portion 20. The pivotal travel of the blade 14″ relative to the blade 14 is limited to the same degree as that of the blade 14′ relative to the blade 14. The oppositely-facing pairs of tangs of the respective first interlocking portions and second interlocking portions maintain the blades in interlocking engagement and allow the necessary range of pivotal motion to open and close the shutter curtain assembly.

Referring to FIG. 2, a cutaway view of the shutter curtain assembly is displayed which shows the interlocking blade portions as previously described in FIG. 4. The shutter curtain is shown in a preferred embodiment in which it extends to cover an opening from opposite sides of the frame 12 that defines the opening. It should also be understood that a single shutter curtain can extend all the way across an opening to cover the opening.

A mounting bracket 34 is attached to side 35 of the frame 12 by any means known in the art. Specifically, a mounting screw 36 for piercing wood or concrete masonry can be employed to mount the bracket 34. The bracket includes a first, or outer, interlocking portion 38 identical in all respects to the first interlocking portion 18 described in FIG. 4. The second, or inner, interlocking portion of a blade 14 is slidably engaged within the interlocking portion 18 of the bracket 34. A succeeding blade 14′ is mounted to the end of the first blade 14 as previously described.

Referring again to FIG. 2, and further to FIG. 5, an elongated member 40 extends the height of the framed aperture at a point midway between the opposite sides of the aperture. The member 40 is separated into a first engaging portion 42 and a second engaging portion 44. The first engaging portion 42 is substantially rectangular in shape and terminates in an outwardly flared first edge 46 and an outwardly flared second edge 48. The second engaging portion 44 is much smaller in size than the first engaging portion 42 and terminates in an edge 50 and an edge 52. The edges 50 and 52 are inwardly pointed and abut against inwardly-directed portions 54 and 56 extending from the edges 46 and 48 of the first engaging portion 42 when the second engaging portion is slidingly locked into place within the first engaging portion.

A blade portion 58 similar in all respects to the blade portions previously described is formed as one piece at 60, with the first engaging portion 42. Similarly, a blade portion 62 is likewise attached to an opposing end of the second engaging portion 44, at 64. A normal blade portion 14″ attaches to a second, or inner, interlocking portion of the blade 58 and a likewise normal blade portion 14′ attaches to a second interlocking portion of the blade 62 as previously described.

A key and lock assembly 64 may be positioned at the overlapping first and second engaging portions of the elongated member and enables the user to lock the shutter assembly in place in an unfolded position.

Referring again to FIG. 2, a pair of upper-locking pins 66 are provided and are inserted within the semi-cylindrical channels of the first interlocking portions of blade portions 58 and 62 at their connection to the engaging portions 42 and 44. The locking pins 66 each include a perpendicular and threadably engaged screw portion which is rotatable within the pins and fixes the pins in position with respect to the cylindrical channels of the first connecting portions. Apertures 68 are formed into the surrounding frame 12, shown in FIG. 1, and receive the pins 66 to lock the engaging portions 42 and 44 in position to the frame once they are snapped together. An identical pair of pins 66 is preferably provided at the bottom of the engaging portions 42 and 44 and locks them into place along the lower surface of the framed aperture by engaging within another pair of apertures 70 formed within the bottom of the frame.

Referring to FIG. 3, a side cutaway view of the shutter curtain assembly is shown. A guide assembly 72 defining a channel 74 extends from one side of the aperture to the other side of the aperture. The guide assembly 72 permits the opposing halves of the shutter curtain to be drawn back to the sides of the frame when it is desired to open the shutter.

Referring again to FIG. 2, a connection 76 and a connection 78 between respective first and second blade interlocking portions is shown. Specifically, connection 76 interlocks blades 14′ and 62 and connection 78 interlocks blades 14 and 58. These connections are the same as described in interlocking blade portions of FIG. 4 and allow the blades to pivot relative to each other for a given degree until opposing tangs of the first and second interlocking portions come into abutting contact.

Referring again to FIG. 3, a mounting portion 80 extends from the connection 76 upwardly past the upper edge of the respective blades 14′ and 62. A bracket 82 is attached by a bolt 84 across the top of the mounting portion 80. A first roller 86 and a second roller 88 extend from opposite sides of the bracket 82 and are restrained to travel within grooves formed within the guide assembly 72. The first roller 86 and second roller 88 are preferably attached to the bracket 82 by screws, rivets or welding as is commonly known in the art. An outer connection 90 is shown between the blades 14 and 14′ and is guided during travel of the shutter curtain along a forward portion 92 of the guide assembly 72 by a flange 94 which supports the forward portion 92.

The weight of the shutter curtain is entirely supported by the upper guide assembly 72 and a lower guide plate 96 is attached along the lower edge of the frame to guide the lower edges of the shutter assembly. Specifically, the lower guide plate 96 is shaped as an interior channel at 98 to guide a corresponding lower portion 100 of the connection 78 between the blades 14 and 14′. A similar extending portion 102 of the connection 90 is guided along the front of the lower guide plate 96. The side view of FIG. 3 only shows the mounting of connection 76 within the guide assembly, however connection 78 is identically mounted within the guide assembly.

In operation, the shutter curtain assembly is normally in an unfolded and covered position as shown in FIG. 1. In order to open the shutter assembly, the upper and lower pairs of locking pins 66 secured within the engaging portions 42 and 44 are loosened and slid out of the apertures 68 and 70 formed in the upper and lower edges of the frame and extending the height of the frame at its most central point. The key lock assembly 64 is then unlocked so that the engaging portion 42 can be separated from the engaging portion 44. The half of the shutter curtain extending from the engaging portion 42 is drawn back toward one side of the frame while the half of the shutter curtain extending from the engaging portion 44 is drawn back toward the other side of the frame.

The guide assembly extending along the top of the frame enables the shutter curtain halves to be easily separated and moved to the opposite sides of the frame. The blade portions pivot at their respective interlocking connections to the degree allowed by the oppositely facing tangs until the blade portions are substantially folded against each other. Referring again to FIG. 2, a representation 104 is shown in phantom of the folded blades 14, 14′ and 62. A lower aperture 106 similar to the lower apertures 70 is formed near the edge of the bottom of the frame and receives the lower pin 66 to secure the folded shutter to the side of the frame. A similar aperture is formed along each edge at the top and bottom of the frame to secure the retracted shutters in place.

In this fashion, a shutter curtain assembly constructed of a plurality of individual shutter blade portions may be used to cover a framed aperture even in the face of heavy winds and inevitable impact of objects hurtled at high velocities by such winds. Specifically, the construction of the blade portions with the pivotal and interlocking outer and inner portions can withstand impact forces greatly in excess of previous shutter constructions. Also, the accordion-like shape of the shutter construction causes the impact forces of objects to be partially deflected and more evenly distributed across the length of the construction.

When each opposing blade set 90 is at the extended limit, the center mates 16 and 17 are preferably in contact. Each of the center mates carries a fastener 18 and 19 which cooperate to releasably connect the opposing shutter sets in a continuous barrier spanning the opening 10.

The size of each blade with attached knuckle components and the set angle determines the deployed size of the blade assembly shown in FIG. 1. The size of the particular window, or the dimensions of the particular supporting components, determine the number of blades (including center connections, as discussed below) necessary to cover a particular sized window. The distance between two adjacent blades in the deployed position D and the stacked position S is preferably about 6 inches. To fit a shutter to a window, the number of blade assemblies is determined that will cover the horizontal span of the window. Adjusting the shutters to fit different-sized windows merely requires adding or subtracting the number of blade assemblies to be used.

As shown in FIG. 6, in one embodiment of the invention, the above components are cut and partially assembled for sale as a self-contained kit 600. The kit includes a top upper guide assembly 602 a bottom guide assembly 604, a left door 606, a right door 608, and mounting hardware 610.

The top guide assembly has a guide opening 612 into which shutter wheels 614 are inserted to allow the shutter doors 606, 608 to slide between their deployed position and their stacked position. The top guide also has mounting holes 616 pre-drilled along its length for mounting the top guide 602 to a fixed structure such as a wall.

A spacing lip 617 extends from the guide portion so that it is positioned between the wheels 614 of the shutter doors 606, 608 and nylon protrusions 618 which extend from the joints 620 between the blades 622 of the shutter doors 606, 608.

The bottom guide assembly 604 is preferably identical to the upper guide assembly. This reduces manufacturing costs and makes installation easier, since a homeowner or business cannot mistakenly install a bottom guide assembly 604 in place of an upper guide assembly 602. However, the invention is not so limited. For example, when the kit is intended to extend to the floor (e.g., to protect a door), a bottom guide assembly 1100 as shown in FIG. 11 could be used.

The shutter doors 606, 608 have guide wheels 614 fixed to the joints 620 closest to the fixed structure against which the shutter is being installed. Preferably, the joints 620 alternate between having a guide wheel 614 and a nylon protrusion 618, which reduces manufacturing costs and makes installation easier, since less guide wheels 614 have to be aligned to the guide portion 612 of the upper guide assembly 602. However, the invention is not so limited, and other configurations of wheels and bushings (including all wheels and no bushings) could be used.

The shutter joints 620 farthest from the fixed structure preferably have nylon protrusions 614 attached. The spacing lip 617 of the upper guide assembly 602 keeps these protrusions 614 in a generally fixed position with respect to the joints 620 closest to the fixed structure.

An outer support 624 is attached to the outermost blade 622 of the door 606, 608. The support 624 has holes 626 for attaching the outer support 624 to the upper and lower guide assemblies 602, 604.

The inner-most blades of the shutter doors 606, 608 are locking blades 628, 630. They have a locking mechanism 632 towards the vertical center of the shutter doors 606, 608. The locking mechanism 632 (not shown in its entirely) is preferably outward-facing so it can be locked and unlocked from outside a building. However, it can also be inward-facing so it can be unlocked from inside an opening in the building. Alternatively, the locking blades 628, 630 can have multiple locking mechanisms 632 spaced apart in a vertical direction.

FIGS. 7A and 7B show views of top guide 602. Top guide 602 has a predetermined length L2, that is preferably pre-cut to accommodate common opening widths, such as standard door or window widths. Top guide 602 has mounting holes 616 pre-drilled along the length thereof, preferably spaced at equal lengths of a predetermined distance L1. One of the holes 616C is preferably located substantially at the center of top guide 802. This substantially central location will facilitate installation as discussed below. The top guide may be fixed, preferably by screws or bolts 610 to a fixed structure 700. Screw holes 702 are for securing the side support 624 of the shutter doors 606, 608 to the top guide assembly 602.

Spacing lip 617 ends in a flange 704 against which nylon projections 618 abut, particularly when the shutter doors 606, 608 are in their closed position. When the shutter doors 606, 608 are open, the nylon protrusions 618 farthest from the fixed structure 700 generally are positioned away from the flange 704 because the blades 622 are wider than the distance from the guide 612 to the flange 704.

Although FIG. 7A shows a vertical fixed structure 700, the fixed structure may be horizontal or angular. Also, although FIGS. 7A and 7B illustrate a top guide 602 affixed directly to the fixed structure 700, a top guide may alternatively be fixed to a second structure, such as a metal brace, which is fixed to the fixed structure. FIG. 8 illustrates an embodiment of a top guide 802 fixed to a metal brace 804 by a bolt 808. The metal brace 804 is fixed to fixed structure 800 by a second bolt or screw 810.

FIG. 9 shows a pre-assembled left door 906. It includes a left support of an outer support 924, a plurality of plane blades 922, and a locking blade 928 with a locking mechanism 932. The individual plane blades 922 are the same as blade portion 14 above, and engage with each other by coaxial alignment and insertion of the first interlocking portion 18 and second interlocking portion 20. The outer support has a protrusion identical to second interlocking portion 20 to receive and connect with the first interlocking portion 18 of the adjacent (leftmost) plane blade. The lock blade 928 has a protrusion identical to first interlocking portion 18 to receive and connect with the second interlocking portion 20 of the adjacent (rightmost) plane blade.

The accordion components are held together by accordion pins inserted into the shaft of portion at the joint 920 of two adjoining blades 922.

To install, the user identifies the center of the opening that is to be covered. Top guide 602 is then placed with its center hole 616C substantially in alignment with the center of the window, although several inches above the opening to provide clearance. A screw or bolt 610 is inserted through the hole 616C to support top guide 602 on the structure. A level is preferably used to ensure the top rail 602 is horizontal before the remaining mounting hardware is installed to securely attach top rail 602 to the building.

The pre-assembled left door 606 is then attached to the top guide 602 by inserting the wheels 614 into the guide 612 so that the metal spacer lip 617 is between the nylon projections 618 farthest from the window and the wheels 614 of the corresponding blades 622. The left support 624 which is pre-attached to the accordion door 606 is then fixed to the top guide 602 with mounting hardware 634, such as screws or bolts.

Next, the right door 608 is attached to the top guide 602 in the same manner. First, the wheels 614 are inserted into the top guide 602 so that the metal spacing lip 617 is between the nylon projections 618 farthest from the window and the wheels 614 of the corresponding blades 622. The right support 636, which is pre-attached to the right accordion door 608, is then fixed to the top guide 602 with mounting hardware 634, such as screws or bolts.

With both doors 606, 608 in an open position, the bottom guide 604 is attached. This is done by holding the bottom guide 604 so that the nylon projections 618 closest to the fixed structure, such as a wall, are inside the guide 612, and the nylon projections 618 farthest from the wall are on the opposite side of the metal lip 617 than the wall-side nylon projections 618. The left support 624 is then secured to the bottom guide 604 by mounting hardware 634. Preferably, one side of the shutter system is then plumbed, and mounting hardware 610 is inserted into the screw hole 616 of the bottom guide 604 closest to the plumbed side of the shutter system to fix the bottom guide 604 against the fixed structure, and to fix the shutter system in a vertically plumbed position. Next, the right support 636 is secured to the bottom guide 604 by mounting hardware 634. Finally, the bottom guide 604 is secured to the fixed structure, such as a wall, by mounting hardware 610.

To lock the shutter doors 606, 608, the doors are closed, and the locking mechanism 632, preferably a key lock, is activated.

A shutter hold-back device 1000, as shown in FIGS. 10 a and 10 b, may be used to keep the shutter doors 606, 608 open. The shutter hold-back device 1000 is preferably plastic and flexible enough to be inserted into and removed from the guide portion 612 of the top and bottom guide assemblies 602, 604. It has two prongs 1002 for being inserted into the hollow bottom guide portion 612 of the bottom guide 604. Surface 1004 rests on the top surface of bottom guide 604. The hold-back device's side edge 1006 rests against the locking blade 630, and a tab 1008 allows for easy insertion and removal of the hold-back device 1000 into and from the bottom guide 604. When inserted, the outward force of prongs 1002 against the inner walls of guide portion creates a pressure lock which prevents movement of the shutter blades toward the deployed position.

It is noted that the foregoing examples have been provided merely for the purpose of explanation and are in no way to be construed as limiting of the present invention. While the present invention has been described with reference to certain embodiments, it is understood that the words which have been used herein are words of description and illustration, rather than words of limitation. Changes may be made, within the purview of the appended claims, as presently stated and as amended, without departing from the scope and spirit of the present invention in its aspects. Although the present invention has been described herein with reference to particular means, materials and embodiments, the present invention is not intended to be limited to the particulars disclosed herein; rather, the present invention extends to all functionally equivalent structures, methods and uses, such as are within the scope of the appended claims. 

1. A method for manufacturing protective shutters comprising: shaping metal to form shutter components, said shutter components comprising at least a top guide piece and a bottom guide piece, a plurality of shutter blades, and side supports; cutting said shutter components to predetermined dimensions; drilling screw holes into said shutter components at predetermined locations; providing a plurality of guide wheels for guiding the shutter blades along a hollow portion in the top guide piece; providing a plurality of protruding pieces for protruding from joints where two shutter blades attach and for guiding said shutter blades along said top and bottom guide pieces; and providing mounting hardware for attaching said protective shutters to a fixed structure and for attaching said shutter components together, wherein all of said shutter components, guide wheels, protruding pieces, and mounting hardware are for being packaged together for delivery to a recipient.
 2. The method of claim 1, further comprising pre-inserting said guide wheels into joints where said shutter blades meet before delivery to a recipient.
 3. The method of claim 1, further comprising pre-inserting said protruding pieces into joints where said shutter blades meet before delivery to a recipient.
 4. The method of claim 1, further comprising pre-attaching said shutter blades to one another to form at least one shutter door before delivery to a recipient.
 5. The method of claim 4, further comprising pre-attaching a side support to an end of said at least one shutter door before delivery to a recipient.
 6. The method of claim 5, wherein said shutter components further comprise at least one locking blade, and the method for manufacturing protective shutters further comprises attaching the at least one locking blade to an end of said at least one shutter door opposite the side support end.
 7. The method of claim 1, wherein said shutter components further comprise a shutter hold-back device.
 8. The method of claim 1, wherein said protruding pieces are made of nylon or plastic.
 9. The method of claim 1, wherein said shutter components are made of aluminum.
 10. The method of claim 9, wherein the shutter components are formed in an aluminum-extrusion process.
 11. The method of claim 7, wherein the shutter hold-back device is made of either nylon or plastic. 